Inside out: optimization of lipid nanoparticle formulations for exterior complexation and in vivo delivery of saRNA

Anna K Blakney,Paul F Mckay,Yoann Aldon,Robin J Shattock,Bárbara Ibarzo Yus

doi:10.1038/s41434-019-0095-2

Anna K Blakney, Paul F Mckay + Show 3 more

Open Access

https://doi.org/10.1038/s41434-019-0095-2

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Journal: Gene Therapy	Publication Date: Jul 12, 2019
Citations: 143	License type: open-access

Affiliation: Imperial College London

Abstract

Self-amplifying RNA (saRNA) is a promising biotherapeutic tool that has been used as a vaccine against both infectious diseases and cancer. saRNA has been shown to induce protein expression for up to 60 days and elicit immune responses with lower dosing than messenger RNA (mRNA). Because saRNA is a large (~9500 nt), negatively charged molecule, it requires a delivery vehicle for efficient cellular uptake and degradation protection. Lipid nanoparticles (LNPs) have been widely used for RNA formulations, where the prevailing paradigm is to encapsulate RNA within the particle, including the first FDA-approved small-interfering siRNA therapy. Here, we compared LNP formulations with cationic and ionizable lipids with saRNA either on the interior or exterior of the particle. We show that LNPs formulated with cationic lipids protect saRNA from RNAse degradation, even when it is adsorbed to the surface. Furthermore, cationic LNPs deliver saRNA equivalently to particles formulated with saRNA encapsulated in an ionizable lipid particle, both in vitro and in vivo. Finally, we show that cationic and ionizable LNP formulations induce equivalent antibodies against HIV-1 Env gp140 as a model antigen. These studies establish formulating saRNA on the surface of cationic LNPs as an alternative to the paradigm of encapsulating RNA.

Highlights

Biotherapeutics based on messenger RNA are a promising strategy for both vaccines and protein replacement therapy
All Lipid nanoparticles (LNPs) were observed to have a similar polydispersity index (PDI) of ~0.2, indicating that there was a consistent range of particle sizes, irrespective of the arrangement of the Self-amplifying messenger RNA (mRNA) (saRNA)
We show that LNPs formulated with cationic lipids and saRNA adsorbed to the surface efficiently deliver RNA in vitro and in vivo, with equivalent protein expression to LNPs formulated with an ionizable lipid and encapsulated RNA

Summary

Introduction

Biotherapeutics based on messenger RNA (mRNA) are a promising strategy for both vaccines and protein replacement therapy. MRNA has been used preclinically for a variety of vaccine indications, including infectious diseases such as influenza [1, 2], rabies virus [3], RSV [4], HIV-1 [5, 6], HCV [7], Zika virus [8], and Ebola virus [9], as well as for cancer vaccines, including lung cancer [10], prostate cancer [11], pancreatic cancer [12], and melanoma [13]. A number of mRNA vaccines against both infectious disease and cancer indications are currently being tested in various human clinical vaccine trials at different stages [14]. Whether mRNA (2000–5000 nt) or saRNA (8000–10,000 nt) is used for gene delivery, it is necessary to pair it with a delivery platform in order to enhance cellular uptake

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